A divergence‐free interpolation scheme for the immersed boundary method

Muldoon, Frank; Acharya, Sumanta

doi:10.1002/fld.1565

Cited by 30 publications

(14 citation statements)

References 21 publications

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“…Thus, strict conservation of quantities such as mass, momentum or kinetic energy is not observed near the irregular boundary. The most severe manifestations of these shortcomings is the occurrence of non-divergence free velocities or unphysical oscillations of the pressure in the vicinity of the immersed boundary [43,30]. Numerous revisions of these interpolations are still proposed for improving the accuracy and consistency of this class of IB methods [30,3,49,43].…”

Section: Introductionmentioning

confidence: 98%

The LS-STAG method: A new immersed boundary/level-set method for the computation of incompressible viscous flows in complex moving geometries with good conservation properties

Cheny

Botella

2010

Journal of Computational Physics

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Section: Introductionmentioning

confidence: 98%

The LS-STAG method: A new immersed boundary/level-set method for the computation of incompressible viscous flows in complex moving geometries with good conservation properties

Cheny

Botella

2010

Journal of Computational Physics

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“…The coupling of momentum forcing methods with projection schemes introduces difficulties in imposing at the same time level the contuinity equation and the boundary conditions on the immersed interface (see [9] for example). The incompressibility of the flow may even be violated in the vicinity of the immersed boundary [10]. This may result in serious diffulties when computing boundary layers at high Reynolds number.…”

Section: Introductionmentioning

confidence: 99%

A second-order cut-cell method for the numerical simulation of 2D flows past obstacles

Bouchon¹,

Dubois²,

James³

2012

Computers & Fluids

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We present a new second-order method, based on the MAC scheme on cartesian grids, for the numerical simulation of two-dimensional incompressible flows past obstacles. In this approach, the solid boundary is embedded in the cartesian computational mesh. Discretizations of the viscous and convective terms are formulated in the context of finite volume methods ensuring local conservation properties of the scheme. Classical second-order centered schemes are applied in mesh cells which are sufficiently far from the obstacle. In the mesh cells cut by the obstacle, fisrt-order approximations are proposed. The resulting linear system is nonsymetric but the stencil remains local as in the classical MAC scheme on cartesian grids. The linear systems are solved by a direct method based on the capacitance matrix method. The time integration is achieved with a second-order projection scheme. While in cut-cells the scheme is locally first-order, a global second-order accuracy is recovered. This property is assessed by computing analytical solutions for a Taylor-Couette problem. The efficiency and robustness of the method is supported by numerical simulations of 2D flows past a circular cylinder at Reynolds number up to 9 500. Good agreement with experimental and published numerical results are obtained.

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“…A well known issue with this class of algorithms is their tendency to introduce large non-physical pressure oscillations (see [8] for example). Muldoon [9] even showed that the pressure could locally increase without bound as the time step goes to zero. These oscillations are caused by the lack of smoothness of the velocity across the boundary before the projection step [10].…”

Section: Introductionmentioning

confidence: 99%

Accurate Cartesian-grid simulations of near-body flows at intermediate Reynolds numbers

Maertens

Weymouth

2015

Computer Methods in Applied Mechanics and Engineering

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An accurate Cartesian-grid treatment for intermediate Reynolds number fluid-solid interaction problems is described. We first identify the inability of existing immersed boundary methods to handle intermediate Reynolds number flows to be the discontinuity of the velocity gradient at the interface. We address this issue by generalizing the Boundary Data Immersion Method (BDIM, Weymouth and Yue, J. Comp. Phys., vol. 230, 2011), in which the field equations of each domain are combined analytically, through the addition of a higher order term to the integral formulation. The new method, featuring a second-order convolution, retains the desirable simplicity of direct forcing methods and smoothes the velocity field at the fluid-solid interface while removing its bias. This results in accurate flow predictions and pressure fields without spurious fluctuations, even at high Reynolds number where the method is second order in the L 2 norm. A treatment for sharp corners is also derived that significantly improves the flow predictions near the trailing edge of thin airfoils. The second-order BDIM is applied to unsteady problems relevant to ocean energy extraction as well as animal and vehicle locomotion for Reynolds numbers up to 10 5 .

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A divergence‐free interpolation scheme for the immersed boundary method

Cited by 30 publications

References 21 publications

The LS-STAG method: A new immersed boundary/level-set method for the computation of incompressible viscous flows in complex moving geometries with good conservation properties

The LS-STAG method: A new immersed boundary/level-set method for the computation of incompressible viscous flows in complex moving geometries with good conservation properties

A second-order cut-cell method for the numerical simulation of 2D flows past obstacles

Accurate Cartesian-grid simulations of near-body flows at intermediate Reynolds numbers

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